Detecting a blocker RFID tag

ABSTRACT

For detecting a blocker RFID tag, the following steps are conducted. First, a random identifier of a given bit length is created. Alternatively, an identifier is selected out of a probing set, which is stored on a data storage device. The probing set comprises of identifiers, which are not being used as identifiers for a given set of RFID tags. In a second step, a response from all RFID tags is requested having an identifier matching the random identifier or, respectively, the selected identifier. In a third step, it is determined, depending on receiving or not receiving a response, whether the blocker RFID tag is present.

TECHNICAL FIELD

The present invention relates to a method for detecting a blocker RFIDtag. It further relates to a device for detecting a blocker RFID tag.RFID refers to Radio Frequency Identification.

BACKGROUND OF THE INVENTION

RFID tags are available in different materials and shapes. Theytypically comprise a microchip with an antenna for communicating withreaders over a radio frequency, and a storage device, in which a fullidentifier is stored. When requested by a reader, an RFID tag respondsby transmitting its full identifier. It may, however, also upon requestjust transmit part of its full identifier. There have been approaches ofstandardizing the full identifiers of RFID tags. Such an approach is theso-called EPC global standard. EPC stands for Electronic Product Code,which is an identification scheme designed to enable the uniqueidentification of all physical objects. The EPC code ranges from 64 to256 bits in length, which encodes four distinct information fields. Incase of the EPC 96-bit code, the first field (the header) is defined forbits 0 to 7 and indicates the length of the code. The second field isthe so-called EPC manager covering, for example, bits 8 to 35 andtypically contains information about the manufacturer of the product theRFID tag is attached to. The third field is the so-called object class,covering, for example, bits 36 to 59 and referring to the exact type ofproduct in the same manner as a stock keeping unit. The fourth field isreferred to as the serial number and may cover bits 60 to 96. Thisfourth field provides a unique 36-bit identifier for individual productsdepending on the length of the EPC code. It may be possible toindividually mark every product with a unique full identifier.

Passive RFID tags are a class of simple tags that when queried by areader will respond with their tag information (identifier). Such tagstypically have minimal computational logic, and receive power from thereaders, and are relatively cheap to manufacture. Many business casesfor the deployment of RFID technology in supply chains are predicated onthe widespread deployment of passive tags to replace manual inventoryingsolutions based on bar code systems. RFID technology enables thetracking of individual products through production, distribution andsale, when RFID readers are installed at various locations in the supplychain. Further, in retail stores, RFID tagging may reduce the timerequired to actually pay for goods a consumer intends to purchase byextracting the pricing information automatically, and thus rendering itunnecessary to take the goods out of a shopping cart.

The usefulness of RFID technology directly depends on the quantity andaccuracy of the tag information collected by readers. Business processesthat depend on RFID information for their successful and timelycompletion can be disrupted by “malicious” tags that introduce spuriousinformation to a reader or block genuine information from reaching areader. The integrity of business processes that depend on RFID taginformation can be protected if there are methods to quickly identifyand isolate malicious tags.

However, there are also security and privacy concerns related to RFID.The paper, “An Introduction to RFID-Information Security And PrivacyConcerns” by Björn Johannsen explains basic RFID concepts and alsoconsiders the problem of information security. There are security andprivacy concerns both for the supply chain, and also for consumers whopurchase goods containing passive RFID tags.

With respect to supply chains, the usefulness of RFID technologydirectly depends on the quantity and accuracy of the tag ID informationcollected by readers. Business processes that depend on RFID informationfor their successful and timely completion can be disrupted by“malicious” tags that introduce spurious information to a reader orblock genuine information from reaching a reader. The integrity ofbusiness processes that depend on RFID tag information can be protectedif there are methods to quickly identify and isolate malicious tags.

With respect to consumers, one threat that has been identified with theintroduction of passive tags into consumer products is that consumerprivacy may be eroded. The issue here that passive tags are still ableto transmit their identification information beyond the point of sale,and in fact will willingly disclose this information to any (compatible)reader. While this may be considered an advantage in the supply chainfor consumer products, most consumers do not want the tag informationassociated with their purchases to be read by readers placed in otherstores, or in public places in general. Since passive tags transmit thesame information for each read request, it is possible for a consumer tobe physically tracked by the reading of tag information associated withtheir purchases. The tags could also reveal consumer purchasingpreferences.

The Blocker Tag is a technology for preventing tag information frombeing read by a reader unknown to a person carrying one or severaltagged items. Read requests to a tag could be physically blocked bysimply jamming the radio transmission between a tag and a reader. TheBlocker Tag prevents tag reading not by jamming the transmissionchannel, but rather by preventing the read protocol between the tag andthe reader from completing. In what follows, an introduction to RFIDread protocols and an explanation of the operation of the Blocker Tag isgiven.

Many RFID applications require a reader to read all tags that arecurrently in its proximity, sometimes referred to as inventorying thetag population (of the reader). The channel between the reader and itstags is a broadcast channel, and the channel from tags to the readeronly supports one tag sending at a time. If multiple tags send theirinformation during the same time instance then a collision occurs andtypically no tag information can be recovered by the reader. The readermust then use an anti-collision protocol whose purpose is to singulate(or isolate) each tag in turn, so that the singulated (or isolated) tagcan send its information while the other tags remain silent (until theyin turn are singulated).

A common singulation method is the so-called tree-walking singulationalgorithm. The tree-walking singulation algorithm enables the reader toidentify the serial numbers of nearby tags individually by means of abit-by-bit query process resembling a depth-first search of a binarytree. If the RFID tags in a given system bear unique identifiers of somefixed bit length k, then the set of all possible k-bit identifiers canbe viewed as the leaves of a standard binary tree of depth k. The rootof this tree has a depth of 0 and is labeled with the empty string. Anode of depth d is labeled with a binary string x of length d. If d issmaller than k, then the node has two children at depth d+1: a “leftchild” with label x0 (x∥0) and a “right child” with label x1 (x∥1). Onemay regard the branches (children) of a given node in this tree asbearing labels “0” and “1”, respectively associated with the left andright branches. Thus a node at depth d in this tree may be uniquelyidentified by a binary prefix B=b₁b₂ . . . b_(d), representing thesequence of branches traversed in a path from the root to the node. Itfollows that each of the 2^(k) leaves in the tree is associated with aunique k-bit string. Each such leaf may be viewed as a unique k-bitstring that could be allocated to the serial number of a tag.

Given this interpretation of the tags identifiers to be read, thetree-walking algorithm proceeds as follows. The basic step of thealgorithm is for the reader to broadcast a prefix B to all tags. Eachtag receives B, and if B is a prefix of its identifier, the tag thentransmits information to the reader. Each tag makes this decisionindependently. The reader waits for responses and observes one of threeoutcomes:

-   -   No responses: meaning no tag had B as a prefix. In this case B        cannot be used to singulate a tag, so the reader selects a new        value of B.    -   One response: meaning that exactly one tag (say T) has B as a        prefix. The reader can now use B to address B uniquely, and can        read the tag information from T while the other tags remain        silent. Once T has been read, the reader can select a new value        of B and singulate any remaining unread tags.    -   A collision occurs: meaning that more than one tag matches B as        a prefix. In this case B is too general (that is, too short) to        singulate a single tag, and therefore B must be extended. The        reader then attempts to singulate tags using the prefixes B∥0        and B∥1.

In practice, the values of B are chosen to perform a recursivedepth-first search of the binary tree defined by the tags identifiers tobe read, which is equivalent to walking a binary tree. Initially theprefix B is set to the empty string (of zero length), which matches alltags identifiers, and then extended to 1 and 0 initially. The fulloutput of the tree-walking algorithm is a list of the ID numbers of allRFID tags within range. The running time of this algorithm is bounded bythe product of k and the number of tags being read. In practice, ashopping cart full of goods should be scannable in a few seconds.Importantly, the tags must follow the protocol to guarantee thesingulation of each tag. In particular, when B is not a prefix of atag's identifier, then the tag must remain silent.

The main use of a blocker tag is to maintain the privacy of a person inpossession of passively tagged goods, where the privacy of the personmay be threatened if the information contained these tags can beextracted by any readers sufficiently close to the person. Blocker tagsinterfere with the tree-walking singulation algorithm by participatingin singulation protocol in non-compliant manner, which may be thought ofas a type of passive jamming. If a reader broadcasts a given prefix B,and detects a collision, then the reader extends B and makes anotherrequest, eventually expecting a singulation. However, the blocker tag isdesigned to respond to every prefix broadcast from a reader, so ifanother tag responds to the same request, then a collision will begenerated. In particular, if the blocker tag is protecting theidentifier of a given tag T, then each response from T will result in acollision since the blocker tag will also be responding. So the blockertag “blocks” information from being read by generating collisions in theRF channel. In this manner, for each request the reader either detects acollision (and gains no information about the tags responding) or onlyreads the information sent by the blocker tag (and still gains noinformation about the other tags). When the reader attempts to resolve adetected collision by extending the prefix, the blocker tag will causeanother collision for the extended prefix, and so on.

A blocker tag effectively overwhelms the tree-walking singulationalgorithm by forcing it to sweep the full space of all possible RFID tagidentifiers. If the reader had enough time, memory, and processing powerto complete the tree-walking algorithm in these circumstances, it wouldoutput the entire set of all 2^(k) possible tag serial numbers. This setis very large, however—a size of at least 2⁶⁴ in even the most basicsystem—and the reading process is designed to execute very rapidly. Inpractice, therefore, the reader may be expected to stall after reachingonly a few hundred leaves in the tree. A net effect is that the fullblocker tag blocks the reading of all other RFID tags.

The blocker tag may, however, also be designed to selectively block onlya given range of identifiers, and to remain silent otherwise. A blockerRFID tag is referred to as “a full blocker” or “a universal blocker” ifit simulates the full set of all 2^(k) possible RFID tag serial numbers.Thanks to the structure of the tree-walking algorithm, such blocking maybe accomplished quite easily. Whenever the reader queries RFID tags inthe subtree of a given node b for the next bit value, the blocker RFIDtag simultaneously broadcasts both a “0” bit and a “1” bit. The blockerRFID tag may require two antennae to do this. This forced collisiondrives the reader to recourse on all nodes, causing the reader toexplore the entire binary tree.

The blocker RFID tag may also be refined so as to simulate and,therefore, effectively block just a subset of tags. Such a blocker RFIDtag may be referred to as “partial” blocker RFID tag or a “selective”blocker RFID tag. For example, a selective blocker RFID tag might replyto the reader only during execution of the tree-walking in the leftsubtree of the root. This selective-blocking feature will have theeffect of obstructing only the reading of tags that bear a “0” prefix intheir serial numbers. RFID tags with serial numbers that begin with a“1” bit could be read without interference. In this manner, theselective blocker RFID tag can target a particular zone for protection.

While blocker tags can be used to protect the privacy of informationcontained on (passive) RFID tags, unfortunately the same idea hasmalicious applications. If a (universal) blocker tag is protecting(blocking) the information on tag T from being read, it will in factblock information block all tags in the range of the reader. This isbecause the blocker tag responds to all broadcasted prefixes, not justthe prefixes that match with the identifier of T. Because of thisproperty, blocker tags may be used maliciously, for example, to subvertRFID applications that rely on the quantity and accuracy of theinformation collected by readers. The tagged goods may be in the rangeof the reader, but the blocker tag prevents the reader from extractingthe identifiers of the goods.

It is a challenge to provide a simple method for detecting the presenceof blocker RFID tags amongst the collection of RFID tags within therange of a reader. It is furthermore a challenge to provide a device fordetecting a blocker RFID tag, which enables in a simple way thedetection of blocker RFID tags.

SUMMARY OF THE INVENTION

Therefore, according to one aspect of the invention, a method fordetecting a blocker RFID tag is provided that comprises the steps offirst creating a random identifier of a given bit length. The randomidentifier may thus be a full identifier of the RFID tag, which may bein the case of the EPC standard, for example, a bit length of 96 bits.It may also be just part of the full identifier. In a second step, aresponse from all RFID tags having an identifier matching the randomidentifier is requested. In the third step, it is determined dependingon receiving or not receiving a response whether a blocker RFID tag ispresent.

In an advantageous embodiment of the method, it comprises repeatedlyconducting the first and second steps and determining, depending on anamount of received or not received responses, whether a blocker RFID tagis present. In this way, the probability of correctly detecting blockertags is even more increased. In addition to that, a selective blockertag may be more reliably detected.

According to a second aspect, a method for detecting a blocker RFID tagis provided comprising the steps of first selecting one identifier outof a probing set being stored on a data storage device, said probing setcomprising identifiers, which are not being used as identifiers for agiven set of RFID tags. In a second step, a response from all RFID tagsis requested having an identifier matching the selected identifier. In athird step, it is determined, depending on receiving or not receiving aresponse, whether a blocker RFID tag is present. In this way, theinsight is used that the number space of the respective full identifiersof the RFID tags is generally extremely large.

According to a third aspect of the invention, a device for detecting ablocker RFID tag is provided, the device being designed for firstcreating a random identifier of a given bit length, for secondlyrequesting a response from all RFID tags having an identifier matchingthe random identifier and for thirdly determining, depending onreceiving or not receiving a response whether a blocker RFID tag ispresent.

According to a fourth aspect of the invention, a device for detecting ablocker RFID tag is provided, which is designed for conducting the stepsof first selecting one identifier out of a probing set being stored on adata storage device , said probing set comprising identifiers, which arenot being used as identifiers for a given set of RFID tags, and thirdrequesting a response from all RFID tags having an identifier matchingthe selective identifier and third determining, depending on receivingor not receiving a response, whether a blocker RFID tag is present.

The advantages of the third and fourth aspect of the inventioncorrespond to the advantages of the first and second aspect of theinvention.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention and its embodiments will be more fully appreciated byreference to the following detailed description of presentlyadvantageous but nonetheless illustrative embodiments in accordance withthe present invention when taken in conjunction with the accompanyingdrawings, in which:

FIG. 1 shows an RFID tag system with a reader unit,

FIG. 2 shows a flow chart for determining the presence of a blocker RFIDtag, and

FIG. 3 shows a further flow chart for detecting the presence of theblocker RFID tag. DESCRIPTION OF SYMBOLS 1-4 Regular RFID tag 5 BlockerRFID tag 6 Reader unit 8 Antenna 10 data storage device BL bit lengthBL1 first bit length RAN_ID random identifier REQ Request CTR counterCOLL collision BL_ADD additional bit length RESP response BT blockerRFID tag marker BT[ ] blocker RFID tag marker array TRUE true valueFALSE false value CTR_MAX maximum value i placeholder PS probing setID_S selected identifier t given time t_max maximum time value

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides methods for detecting a blocker RFID tagis provided that comprises the steps of first creating a randomidentifier of a given bit length. The random identifier may thus be afull identifier of the RFID tag, which may be in the case of the EPCstandard, for example, a bit length of 96 bits. It may, however, also bejust part of the full identifier, which includes that the randomidentifier may also not contain the leading bit but rather be positionedsomewhere in the given bit positions of the full identifier. In a secondstep, a response from all RFID tags having an identifier matching therandom identifier is requested. In the third step, it is determineddepending on receiving or not receiving a response whether a blockerRFID tag is present.

By appropriately choosing a given bit length, for example, by choosing agiven bit length of 64 bit, the probability of having a regular RFID tagwhich matches the created random identifier is extremely small and,therefore, a response renders it highly likely that a blocker RFID tagis present. Therefore, blocker RFID tags may be detected with littleeffort and very efficiently. In this respect, it is not required to keepa list of “good” identifiers of RFID tags. Only a random numbergenerator is necessary. In addition to that it is not necessary to havean on-line connection with a back-end database to check the identifierof a scanned RFID tag. Furthermore, it is not necessary to havecooperation between a manufacturer employing the regular RFID tags forits products and an organization hosting the reading process.

In an advantageous embodiment of the method, it comprises repeatedlyconducting the first and second steps and determining, depending on anamount of received or not received responses, whether a blocker RFID tagis present. In this way, the probability of correctly detecting blockertags is even more increased. In addition to that, a selective blockertag may be more reliably detected.

In a further advantageous embodiment of the method, it comprisesrepeatedly conducting the first and second steps and varying the givenbit length. In this way, it may be even harder for smart blocker-tags torecognize that it is tried to detect a blocker RFID tag.

In a further advantageous embodiment of the method, the first step isconducted by creating the random identifier with a given first bitlength. The second step is conducted and upon receiving a responsesignaling a collision of at least two RFID tags respondingsimultaneously, the random identifier is modified by adding a givenamount of bits having a random value. Then, the second step is againconducted with the modified random identifier and it is determineddepending on receiving or not receiving a response whether a blockerRFID tag is present. This has the advantage that the first bit lengthmay be appropriately significantly shorter than the full bit length ofthe full identifier, which causes less effort of conducting the methodin case of the absence of the blocker RFID tag. It ensures at the sametime by appropriately choosing the length of the added bits that thepresence of the blocker RFID tag may with a very high probability bedetected.

The present invention also provides methods for detecting a blocker RFIDtag is provided comprising the steps of first selecting one identifierout of a probing set being stored on a data storage device. The probingset comprising identifiers, which are not being used as identifiers fora given set of RFID tags. In a second step, a response from all RFIDtags is requested having an identifier matching the selected identifier.In a third step, it is determined, depending on receiving or notreceiving a response, whether a blocker RFID tag is present. In thisway, the insight is used that the number space of the respective fullidentifiers of the RFID tags is generally extremely large. Amanufacturer may in many cases not use its full number space, which heis assigned to. Therefore, it is very simple and reliable to use atleast part of this unused number space for detecting the presence of theblocker RFID tag, as none of the regular RFID tags would respond to anidentifier, which is not used as identifier for the given set of RFIDtags. Therefore, this enables a very reliable identification of theblocker RFID tag.

In an advantageous embodiment of the invention, the method comprisesrepeatedly conducting said second and third steps and determining,depending on an amount of received or not received responses, whether amalicious RFID tag is present. This may ensure an even more reliabledetection of a selective blocker RFID tag.

In a further advantageous embodiment of the invention, the probing setis a subset of all identifiers, which are not used as identifiers forthe given set of RFID tags. This enables that only a small number of theidentifiers, which are not being used as identifiers for the given setof RFID tags, need to be stored on the storage device, which has thepositive effect that not that much memory space is used. It further hasthe advantage that possible attackers do not have access to allidentifiers which are not being used as identifiers for the given set ofRFID tags.

In a further advantageous embodiment of the invention, the methodcomprises storing a modified probing set of identifiers, which are notbeing used as identifiers for the given set of RFID tags, when a giventime-related condition is fulfilled. This would even more increase theoverall safety, as attackers would be faced from time to time again withnew identifiers they could not spy out before.

In a further advantageous embodiment of the invention, the probing setcomprises a given number of identifiers being larger than the number ofidentifiers being possibly stored in the blocker RFID tags. This has theadvantage that it is impossible for the blocker RFID tag to store allidentifiers of the probing set.

The present invention also provides devices for detecting a blocker RFIDtag is provided. A device being designed for first creating a randomidentifier of a given bit length, for secondly requesting a responsefrom all RFID tags having an identifier matching the random identifierand for thirdly determining, depending on receiving or not receiving aresponse whether a blocker RFID tag is present.

In an advantageous embodiment of the invention, the device is designedfor repeatedly conducting the first and second steps and determining,depending on an amount of received or not received responses, whether ablocker RFID tag is present.

In a further advantageous embodiment of the invention, the device isdesigned for repeatedly conducting the first and second steps andvarying the given bit length.

In a further advantageous embodiment of the invention, the device isdesigned for conducting the first step by creating the random identifierwith a given first bit length and conducting the second step. It isfurthermore designed for upon receiving a response signal in collisionof at least two RFID tags responding simultaneously to modify the randomidentifier by adding a given amount of bits having a random value andconducting the second step with the modified random identifier anddetermining depending on receiving or not receiving a response whether ablocker RFID tag is present.

The present invention also provides devices for detecting a blocker RFIDtag is provided, which are designed for conducting the steps of firstselecting one identifier out of a probing set being stored on a datastorage device. The probing set comprising identifiers, which are notbeing used as identifiers for a given set of RFID tags, and thirdrequesting a response from all RFID tags having an identifier matchingthe selective identifier and third determining, depending on receivingor not receiving a response, whether a blocker RFID tag is present.

In an advantageous embodiment of the invention, a device is designed forrepeatedly conducting the second and third steps and determining,depending on an amount of received or not received responses, whetherthe blocker RFID tag is present.

In a further advantageous embodiment of the invention, the device isdesigned for the probing set being a subset of all identifiers which arenot being used as identifiers for the given set of RFID tags.

In a further advantageous embodiment of the invention, the device isdesigned for storing a modified probing set of identifiers, which arenot being used as identifiers for the given set of RFID tags, when agiven time-related condition is fulfilled.

In a further advantageous embodiment of the device is designed for theprobing set comprising a given number of identifiers being larger than anumber of identifiers being possibly stored in the blocker RFID tag.

FIG. 1 shows an RFID tag system. It comprises several regular RFID tags1 to 4, of which four are by way of example shown here, they may,however, also be present in a way larger number of, for example, 200regular RFID tags. In addition to that, a blocker RFID tag 5 is present.

The regular RFID tags are RFID tags with identifiers with valididentification numbers for the given business process. They may havefull identifiers, which comply, for example, to the EPC (ElectronicProduct Code) standard. The electronic product code ranges from 64 bitsto 256 bits with four distant fields. The manufacturer of goods, towhich the regular RFID tags 1 to 4 may be attached, may have allocatedcertain parts of the full identifier individually to each of the regularRFID tags. The blocker tag 5 may either be a universal blocker RFID tagor it may also just be a selective blocker RFID tag. It may contain agiven memory space for storing data. In particular the blocker RFID tagmay be a malicious RFID tag.

In addition to that, a reader unit 6 is present, which comprises anantenna 8 for transmitting and receiving signals to and from the regularRFID tags 1-4 and the blocker RFID tag 5. It further comprises a datastorage device 10 and is designed for running programs, which are in thefollowing described by the flow charts of the FIGS. 2 and 3. For thisreason, it comprises respective data processing means.

A first program (FIG. 2) may be started at regular intervals in a stepS1, in which certain parameters may be initialized. In a step S2, alsoreferred to as first step, a random identifier RAN_ID with a given bitlength BL is created. This step can be performed by a random identifiercreator, being implementable in hardware, software or any mix thereof.The given bit length may, for example, be a first bit length, which mayby way of example be, for example, 50 bits. It may, however, also belarger or smaller, for example, 16 or 64 bits. For creating the randomidentifier RAN_ID, preferably a random number generator is provided.

In a step S4, a request REQ is transmitted via the antenna 8 to thepresent regular RFID tags 1 to 4 and the blocker RFID tag 5 to respond,if their respective identifier matches the random identifier RAN_ID. Itis important to note here, that the random identifier RAN_ID may be,depending on the given bit length BL, be just part of the fullidentifier of the respective RFID tags. The regular RFID tags 1 to 4 aredesigned to respond only if their respective identifier matches therandom identifier RAN_ID. However, blocker RFID tag 5 may respond alwaysor just to selective identifiers. This step is referred to as a secondstep and it can be performed by a requestor, being implementable inhardware, software or any mix thereof.

In a step S6, it is determined whether a collision COLL of responses isdetected. This collision may take place if two RFID tags respond at thesame time with different bit values “0” and “1”. Such a collision mayalso take place if the blocker RFID tag 5 is designed for simultaneouslytransmitting bits of value “0” and “1”. If a collision has been detectedin step S6, the bit length of the random identifier RAN_ID created instep S2 may be modified by an additional bit length BL_ADD and in thisway just the additional bits may be added with a random value to thealready existent random identifier RAN_AD in step S8. The step S4 isagain processed. The iterations through the step S8 should be limitedto, at maximum, reaching the bit length BL of a full bit length of thefull identifier. For that reason, the condition in step S6 mayindependently form whether a collision COLL is detected be notfulfilled, if the bit length BL of the random identifier RAN_ID hasreached the full bit length.

If the condition of step S6 is not fulfilled, then in a step S10 it ischecked whether a response RESP has been received upon the request REQof step S4. This step is referred to as a third step and it can beperformed by a determinator, being implementable in hardware, softwareor any mix thereof.

If the condition of step S10 is true, the program proceeds to step S12and sets a blocker RFID tag marker BT on a true value TRUE. This isbased on the assumption that the probability of the regular RFID tag 1-4responding to the random identifier RAN_ID is fairly low. In the case ofa bit length BL of 64, the probability is, for example, only 2⁻⁶⁴. If,however, the condition of step S10 is not fulfilled, the programproceeds to a step S16, where the blocker RFID tag marker BT is markedwith a false value FALSE. The program may be terminated after steps S10and S16.

In an alternative embodiment, the program may proceed to step S18, whenthe condition of step S10 is fulfilled. In the step S18, a blocker RFIDtag marker within a blocker RFID tag marker array BT [], which positionwithin the array is determined by a counter CTR, is given the true valueTRUE and, respectively, in a step S22, a respective false value FALSE isassigned, if the condition in step S10 is not fulfilled. After that, ina step S20, the counter CTR is incremented and it is checked whether thecounter has a value higher than a maximum value CTR_MAX. If this is notthe case, then the program proceeds again to step S2. It is possiblethat it first proceeds to a step S24 where the first bit length BL1 maybe varied, for example, depending on the counter CTR. After step S24,the program then proceeds to step S2.

If the condition of step S20 is, however, fulfilled, then the programproceeds to a step S26, in which a true or, respectively, false valueTRUE, FALSE is assigned to the blocker RFID tag marker BT depending onan amount of received or not received responses, which may, for example,be determined by evaluating the amount of true and, respectively, falsevalues within the blocker RFID tag marker array BT []. For this purpose,a threshold may be given for the amount of true values in order toallocate the true value to the blocker RFID tag marker BT. The programis then terminated in the step S14.

If the blocker RFID tag marker BT has been allocated the true valueTRUE, the reader unit 6 may, for example, signal the presence of theblocker RFID tag in order to enable to physically identify the blockerRFID tag 5 and to remove it.

The program according to FIG. 2 may also be modified in a way that stepsS6 and S8 are not present and the program proceeds directly from step S4to step S10. In this case, also a collision may be interpreted as theresponse RESP.

In a second embodiment of the program according to FIG. 3, the programis started in a step S30. In this step S30, certain variables may beinitialized. In a step S32, it is checked whether a given time t isgreater than a maximum time value t_max. If this is the case, then theprogram proceeds to a step S34. In the step S34, a given probing set PSof identifiers, which are not being used as identifiers for a given setof RFID tags, is stored in the data storage device 10. The probing setPS therefore only comprises identifiers which the manufacturer hasdecided upon not to use as valid identifiers for the objects he wants tomark with the regular RFID tags 1 to 4. A probing set PS stored in thedata storage device 10 is preferably just a subset of all of the bymanufacturer as invalid classified identifiers. In this way, memoryspace may be saved and also a spying out of all of the respectiveidentifiers may be prevented. Preferably the stored probing set PS islarger than a number of identifiers being possibly stored in saidblocker RFID tag 5.

An update of the probing set PS may in step S34 be accomplished byestablishing a communication connection to, for example, a back-enddatabase, which then provides the probing set PS. Preferably, theprobing set PS is changed whenever the new probing set PS is queriedfrom the back-end database. In a simpler embodiment, however, theprobing set PS may be stored in the data storage device 10 and not beupdated after the given time t exceeds the maximum time value t_max.

In a step S36, a selected identifier ID_S is selected from the probingset PS. This step is referred to as a first step and it can be performedby a selector, being implementable in hardware, software or any mixthereof. The selected identifier ID_S may, for example, be randomlyselected from the probing set PS. It is to be noted here that theselected identifier ID_S may have a bit length that is different to thefull bit length of the full identifier for the tags. In step S38, arequest REQ to response is transmitted via the antenna to all RFID tagsbeing present asking them to answer only if their respective identifiermatches the selected identifier ID_S. In step S40, it is then checkedwhether the response RESP has been received by some or one of theidentifier RFID tags. If a response is received in step S40, then theblocker RFID tag marker BT is set on the true value TRUE in step S42.This is based on the fact, that none of the regular RFID tags 1 to 4would respond to the request transmitted in step S38. Therefore, it isreasoned that a response may only come from the blocker RFID tag 5.

If, however, the condition of step S40 is not fulfilled, then theblocker RFID tag marker BT is assigned the false value FALSE in a stepS46. After steps S42 and S46, the program is terminated in a step S44.Actions taken by the reader unit 6 may be the same as the embodiment ofthe program according to FIG. 2. Steps 48, 52, 50, and 54 correspond tothe steps S18, S22, S20, and S26.

Any disclosed embodiment may be combined with one or several of theother embodiments shown and/or described. This is also true for one ormore features of the embodiments. The present invention can be realizedin hardware, software, or a combination of hardware and software. It maybe implemented as a method having steps to implement one or morefunctions of the invention, and/or it may be implemented as an apparatushaving components and/or means to implement one or more steps of amethod of the invention described above and/or known to those skilled inthe art. A visualization tool according to the present invention can berealized in a centralized fashion in one computer system, or in adistributed fashion where different elements are spread across severalinterconnected computer systems. Any kind of computer system—or otherapparatus adapted for carrying out the methods and/or functionsdescribed herein—is suitable. A typical combination of hardware andsoftware could be a general purpose computer system with a computerprogram that, when being loaded and executed, controls the computersystem such that it carries out the methods described herein. Thepresent invention can also be embedded in a computer program product,which comprises all the features enabling the implementation of themethods described herein, and which—when loaded in a computer system—isable to carry out these methods. Methods of this invention may beimplemented by an apparatus which provides the functions carrying outthe steps of the methods. Apparatus and/or systems of this invention maybe implemented by a method that includes steps to produce the functionsof the apparatus and/or systems.

Computer program means or computer program in the present contextinclude any expression, in any language, code or notation, of a set ofinstructions intended to cause a system having an information processingcapability to perform a particular function either directly or afterconversion to another language, code or notation, and/or afterreproduction in a different material form.

Thus the invention includes an article of manufacture which comprises acomputer usable medium having computer readable program code meansembodied therein for causing one or more functions described above. Thecomputer readable program code means in the article of manufacturecomprises computer readable program code means for causing a computer toeffect the steps of a method of this invention. Similarly, the presentinvention may be implemented as a computer program product comprising acomputer usable medium having computer readable program code meansembodied therein for causing a a function described above. The computerreadable program code means in the computer program product comprisingcomputer readable program code means for causing a computer to effectone or more functions of this invention. Furthermore, the presentinvention may be implemented as a program storage device readable bymachine, tangibly embodying a program of instructions executable by themachine to perform method steps for causing one or more functions ofthis invention.

It is noted that the foregoing has outlined some of the more pertinentobjects and embodiments of the present invention. This invention may beused for many applications. Thus, although the description is made forparticular arrangements and methods, the intent and concept of theinvention is suitable and applicable to other arrangements andapplications. It will be clear to those skilled in the art thatmodifications to the disclosed embodiments can be effected withoutdeparting from the spirit and scope of the invention. The describedembodiments ought to be construed to be merely illustrative of some ofthe more prominent features and applications of the invention. Otherbeneficial results can be realized by applying the disclosed inventionin a different manner or modifying the invention in ways known to thosefamiliar with the art.

1. A method for detecting a blocker RFID tag comprising a first step ofcreating a random identifier of a given bit length, a second step ofrequesting a response from all RFID tags having an identifier matchingsaid random identifier, and a third step of determining, depending onreceiving or not receiving a response, whether a blocker RFID tag ispresent.
 2. A method according to claim 1, comprising repeatedlyconducting said first and said second steps and in said third stepdetermining, depending on an amount of received or not receivedresponses, whether said blocker RFID tag is present.
 3. A methodaccording to claim 1, comprising repeatedly conducting said first andsaid second steps while varying said given bit length.
 4. A methodaccording to claim 1, comprising conducting said first step by creatingsaid random identifier with a given first bit length, conducting saidsecond step, upon receiving said response signaling a collision of atleast two RFID tags creating a modified random identifier by adding agiven amount of bits having a random value, conducting again said secondstep with said modified random identifier and conducting said third stepfor determining, depending on receiving or not receiving said response,whether said blocker RFID tag is present.
 5. A method for detecting ablocker RFID tag, comprising a first step of selecting one identifierout of a probing set being stored on a data storage device, said probingset comprising identifiers, which are not being used as identifiers fora given set of RFID tags, a second step of requesting a response fromall RFID tags having an identifier matching said selected identifier(ID_S) and a third step of determining, depending on receiving or notreceiving said response, whether said blocker RFID tag is present.
 6. Amethod according to claim 5, comprising repeatedly conducting said firstand second steps and said third step of determining, depending on anamount of received or not received responses, whether said blocker RFIDtag is present.
 7. A method according to claim 5, with said probing setbeing a subset of all identifiers which are not being used asidentifiers for said given set of RFID tags.
 8. A method according toclaim 7, comprising storing a modified probing set of identifiers, whichare not being used as identifiers for a given set of RFID tags, when agiven time-related condition is fulfilled.
 9. A method according toclaim 5, with said probing set comprising a given number of identifiersbeing larger than a number of identifiers being possibly stored in saidblocker RFID tag.
 10. A device for detecting a blocker RFID tagcomprising a random identifier creator for creating in a first step arandom identifier of a given bit length, requestor for requesting in asecond step a response from all RFID tags having an identifier matchingsaid random identifier, and a determinator for determining in a thirdstep, depending on receiving or not receiving a response, whether ablocker RFID tag is present.
 11. A device according to claim 10, beingdesigned for repeatedly conducting said first and said second steps andsaid third step of determining depending on an amount of received or notreceived responses whether said blocker RFID tag is present.
 12. Adevice according to claim 10, being designed for repeatedly conductingsaid first and said second steps while varying said given bit length.13. A device according to claim 10, being designed for conducting saidfirst step by creating said random identifier with a given first bitlength, conducting said second step, upon receiving said responsesignaling a collision of at least two RFID tags respondingsimultaneously modifying said random identifier by adding a given amountof bits having a random value, conducting said second step with saidmodified random identifier and conducting said third step ofdetermining, depending on receiving or not receiving said response,whether said blocker RFID tag is present.
 14. A device for detecting ablocker RFID tag, comprising a selector for conducting a first step ofselecting one identifier out of a probing set being stored on a datastorage device, said probing set comprising identifiers, which are notbeing used as identifiers for a given set RFID tags, a requestor forconducting a second step of requesting a response from all RFID tagshaving an identifier matching said selected identifier and adeterminator for conducting a third step of determining, depending onreceiving or not receiving said response, whether said blocker RFID tagis present.
 15. A device according to claim 14, being designed forrepeatedly conducting said first and second steps and said third step ofdetermining, depending on an amount of received or not receivedresponses, whether said blocker RFID tag is present.
 16. A deviceaccording to claim 14, with said probing set being a subset of allidentifiers which are not being used as identifiers for said given setof RFID tags.
 17. A device according to claim 16, being designed forstoring a modified probing set of identifiers, which are not being usedas identifiers for a given set of RFID tags, when a given time-relatedcondition is fulfilled.
 18. A device according to claim 14, beingdesigned for said probing set comprising a given number of identifiersbeing larger than a number of identifiers being possibly stored in saidblocker RFID tag.
 19. A program storage device readable by machine,tangibly embodying a program of instructions executable by the machineto perform method steps for detecting a blocker RFID tag, said methodsteps comprising the steps of claim
 5. 20. An article of manufacturecomprising a computer usable medium having computer readable programcode means embodied therein for causing detection of a blocker RFID tag,the computer readable program code means in said article of manufacturecomprising computer readable program code means for causing a computerto effect the steps of claim
 1. 21. A computer program productcomprising a computer usable medium having computer readable programcode means embodied therein for causing functions of a device fordetecting a blocker RFID tag, the computer readable program code meansin said computer program product comprising computer readable programcode means for causing a computer to effect the functions of claim 10.22. A computer program product comprising a computer usable mediumhaving computer readable program code means embodied therein for causingfunctions of a device for detecting a blocker RFID tag, the computerreadable program code means in said computer program product comprisingcomputer readable program code means for causing a computer to effectthe functions of claim 14.